Soil bacteria showing a potential of chlorpyrifos degradation and plant growth enhancement

Akbar, Shamsa; Sultan, Sikander

doi:10.1016/j.bjm.2016.04.009

ABSTRACT

Background:

Since 1960s, the organophosphate pesticide chlorpyrifos has been widely used for the purpose of pest control. However, given its persistence and toxicity towards life forms, the elimination of chlorpyrifos from contaminated sites has become an urgent issue. For this process bioremediation is the method of choice.

Results:

Two bacterial strains, JCp4 and FCp1, exhibiting chlorpyrifos-degradation potential were isolated from pesticide contaminated agricultural fields. These isolates were able to degrade 84.4% and 78.6% of the initial concentration of chlorpyrifos (100 mg L^-1) within a period of only 10 days. Based on 16S rRNA sequence analysis, these strains were identified as Achromobacter xylosoxidans (JCp4) and Ochrobactrum sp. (FCp1). These strains exhibited the ability to degrade chlorpyrifos in sterilized as well as non-sterilized soils, and were able to degrade 93-100% of the input concentration (200 mg kg^-1) within 42 days. The rate of degradation in inoculated soils ranged from 4.40 to 4.76 mg^-1 kg^-1 d^-1 with rate constants varying between 0.047 and 0.069 d^-1. These strains also displayed substantial plant growth promoting traits such as phosphate solubilization, indole acetic acid production and ammonia production both in absence as well as in the presence of chlorpyrifos. However, presence of chlorpyrifos (100 and 200 mg L^-1) was found to have a negative effect on indole acetic acid production and phosphate solubilization with percentage reduction values ranging between 2.65-10.6% and 4.5-17.6%, respectively. Plant growth experiment demonstrated that chlorpyrifos has a negative effect on plant growth and causes a decrease in parameters such as percentage germination, plant height and biomass. Inoculation of soil with chlorpyrifos-degrading strains was found to enhance plant growth significantly in terms of plant length and weight. Moreover, it was noted that these strains degraded chlorpyrifos at an increased rate (5.69 mg^-1 kg^-1 d^-1) in planted soil.

Conclusion

The results of this study clearly demonstrate that the chlorpyrifos-degrading strains have the potential to develop into promising candidates for raising the productivity of crops in pesticide contaminated soils.

Keywords:
Chlorpyrifos; Bioremediation; Phosphate solubilization; Achromobacter; IAA

Introduction

The extensive use of pesticides through field application, crop spraying, handling, rinsing of containers, accidental spills, etc. has a potential to severely contaminate soil.¹1 Briceño G, Fuentes MS, Palma G, Jorquera MA, Amoroso MJ, Dieza MC. Chlorpyrifos biodegradation and 3,5,6-trichloro-2-pyridinol production by actinobacteria isolated from soil. Int Biodeterior Biodegrad. 2012;73:1-7. Most of the pesticides that are in common usage today are known to adversely affect functional diversity of the soil microbiota leading to loss of soil fertility and plant growth, which in turn put the sustainability of agricultural soil at serious risk.²2 Fang H, Yu Y, Chu X, Wang X, Yang X, Yu J. Degradation of chlorpyrifos in laboratory soil and its impact on soil microbial functional diversity. J Environ Sci. 2009;21:380-386. To add to the complexity of the situation, pesticide residues and their metabolites often infiltrate through the soil surface into the groundwater and cause widespread contamination of aquatic ecosystems.³3 Lu P, Li Q, Liu H, et al. Biodegradation of chlorpyrifos and 3,5,6-trichloro-2-pyridinol by Cupriavidus sp DT-1. Bioresour Technol. 2013;127:337-342.

Chlorpyrifos (CP) is a broad spectrum organophosphate insecticide that is classified as moderately toxic. Since 1960s, CP has been extensively used in the agricultural sector for controlling insect infestations of crops such as cotton, cereals, vegetables and fruits.⁴4 Jabeen H, Iqbal S, Anwar S. Biodegradation of chlorpyrifos and 3,5,6-trichloro-2-pyridinol by a novel rhizobial strain Mesorhizobium sp HN3. Water Environ J. 2015;29:151-160. Although CP is considered only moderately toxic, it is known to possess neurotoxic and immunotoxic properties and has been shown to be harmful to both animals and humans.⁵5 Saulsbury MD, Heyliger SO, Wang K, Round D. Characterization of chlorpyrifos-induced apoptosis in placental cells. Toxicology. 2008;244:98-110. CP has also been reported to cause a reduction in the bacterial, fungal and actinomycete population of the soil⁶6 Shan M, Fang H, Wang X, Feng B, Chu XQ, Yu YL. Effect of chlorpyrifos on soil microbial populations and enzyme activities. J Environ Sci. 2006;18:4-5. and is known to inhibit nitrogen mineralization in soil.⁷7 Menon P, Gopal M, Prasad R. Influence of two insecticides, chlorpyrifos and quinalphos, on arginine ammonification and mineralizable nitrogen in two tropical soil types. J Agric Food Chem. 2004;:7370-7376. Detection of CP contamination in surface water bodies and associated sediments has heightened public concern on the topic⁸8 Marino D, Ronco A. Cypermethrin and chlorpyrifos concentration levels in surface water bodies of the Pampa Ondulada, Argentina. Bull Environ Contam Toxicol. 2005;75:820-826.^,⁹9 Weston DP, You J, Lydy MJ. Distribution and toxicity of sediment-associated pesticides in agriculture-dominated water bodies of California's Central Valley. Environ Sci Technol. 2004;38:2752-2759. and warranted urgent attention and treatment of the problem.

Bioremediation is a method that exploits the potential of microbial degradation for providing a cost-effective and reliable approach to pesticide abatement. Several soil and aquatic environments have been successfully reclaimed from pesticide contamination by using microbes capable of degrading the pollutants.¹⁰10 Brajesh KS, Walker A. Microbial degradation of organophosphorus compounds. FEMS Microbiol Rev. 2006;30:428-471. Hydrolysis, either chemically or as a result of microbial activity, degrades CP by converting it to diethylthiophosphoric acid (DETP) and 3,5,6-trichloro-2-pyridinol (TCP).¹¹11 Anwar S, Liaquat F, Khan QM, Khalid ZM, Iqbal S. Biodegradation of chlorpyrifos and its hydrolysis product 3,5,6-trichloro-2-pyridinol by Bacillus pumilus strain C2A1. J Hazard Mater. 2009;168:400-405. Pesticide degrading bacteria found in soil are known to have multifarious abilities such as phytohormone production, mineral solubilization, N₂-fixation, etc., which are extremely crucial for promotion of plant growth. Presence of the above-mentioned traits underlines and emphasizes the agronomic and environmental significance of such microbes. The potential of microbes to simultaneously detoxify pollutants while enhancing plant growth has been studied previously for pesticides carbofuran and thiamethoxam.¹²12 Bano N, Musarrat J. Characterization of a novel carbofuran degrading Pseudomonas sp. with collateral biocontrol and plant growth promoting potential. FEMS Microbiol Lett. 2004;231:13-17.^,¹³13 Zhou GC, Wang Y, Ma Y, et al. The metabolism of neonicotinoid insecticide thiamethoxam by soil enrichment cultures, and the bacterial diversity and plant growth-promoting properties of the cultured isolates. J Environ Sci Health B. 2014;49:381-390.

The objective of this study was to isolate and characterize CP-degrading bacteria and to determine the degradation potential of these strains in both sterile as well as non-sterile soil. Moreover, plant growth promoting potential of these bacteria was also assessed; and the strains were tested for their ability to bioremediate soil and enhance plant growth in contaminated soil.

Materials and methods

Chemicals and media

Technical grade chlorpyrifos (98%) was obtained from the Ali Akbar group, Pakistan. Analytical grade CP and 3,5,6-trichloro-2-pyridinol (TCP) were purchased from Sigma-Aldrich (St Louis, MO, USA). HPLC grade organic solvents were procured from Merck (Pakistan). Microbial isolations were conducted in a mineral salt medium (MSM) (pH 6.8-7.0) containing (g L^-1) K₂HPO₄, 1.5; KH₂PO₄, 0.5; NaCl, 0.5; (NH₄)₂SO₄, 0.5; MgSO₄·7H₂O, 0.2, and 10 mL of 100× trace element solution. The 100× trace element solution was composed of (mg L^-1) Na₂EDTA·2H₂O, 500; FeCl₂·4H₂O, 143; ZnCl₂, 4.7; MnCl₂·4H₂O, 3.0; H₃BO₃, 30; CoCl₂·6H₂O, 20; CuCl₂·2H₂O, 1.0; NiCl₂·6H₂O, 2.0; Na₂MoO₄·2H₂O, 3.0; and CaCl₂·2H₂O, 100.

Enrichment, selection and identification of chlorpyrifos degrading strains

Soil samples from agricultural fields of Jhang and Faisalabad, Punjab, Pakistan, were used for the purpose of enrichment of chlorpyrifos degrading bacteria. Five grams of soil was added to Erlenmeyer flasks (250 mL) containing 50 mL MSM supplemented with 50 mg L^-1 CP and the culture was incubated at 150 rpm, 30 °C. The enrichment process was conducted over a period of four weeks; following an established protocol,¹⁴14 Akbar S, Sultan S, Kertesz M. Bacterial community analysis in chlorpyrifos enrichment cultures via DGGE and use of bacterial consortium for CP biodegradation. World J Microbiol Biotechnol. 2014;30:2755-2766. at regular intervals of one week each of the culture was transferred into fresh growth medium. Subsequent to the last enrichment process, serial dilutions of the culture were spread on MSM plates containing CP (50 mg L^-1) and the colonies thus isolated were further purified by the streak plate method.

For determining the degradation potential, cultures were grown in triplicate in MSM containing 100 mg L^-1 CP for a period of 10 days and the residual CP concentration was determined by high performance liquid chromatography (HPLC). CP quantification was analyzed on a SYKAM HPLC (Germany) using an S1122 HPLC Pump, S3210 UV detector, S1122 delivery system and Phenomenex C18 reversed-phase column (150 mm). Detector output was processed by the clarity chromatography data system. Samples were eluted using methanol:H₂O:acetic acid (80:20:0.5, v/v) at a flow rate of 1.0 mL min^-1. Detection was performed at 230 nm and the retention times of CP and TCP were determined to be 18.4 and 16.1 min, respectively. Two isolates with the highest CP degradation potential, designated as JCp4 and FCp1, were selected for further study.

Bacterial strains were identified by amplification of the 16S rRNA gene using universal primers 27f and 1492R. Amplification was carried out in a 50 µL reaction mixture containing 20 pmol of primer (F and R) each, 25 µL PCR Master Mix (Thermoscientific) and 20 ng of template DNA. The PCR thermocycling parameters were as follows: initial denaturation at 94 °C for 5 min; followed by 25 cycles of 94 °C (1 min), 50 °C (1 min); 72 °C (1 min); and final extension at 72 °C for 10 min. The amplified PCR products were sequenced and sequence homologies were identified using nBLAST. GenBank accession numbers were assigned for 16S rRNA gene sequences of both the isolates (KJ009240 and KJ009242).

Determination of auxiliary characteristics

Indole acetic acid (IAA) production

LB-broth (50 mL), supplemented with 50, 100 and 150 µg mL^-1 tryptophan, was inoculated with 50 µL of cell suspension (OD₆₀₀ = 0.5) in triplicate and incubated at 35 °C, 120 rpm for 72 h. At 48 and 72 h intervals, the culture was centrifuged and 2 mL of the supernatant was mixed with 4 mL of Salkowski's reagent. Intensity of colour was taken as OD₅₃₅ and the amount of IAA produced was quantified using a standard curve. The effect of CP on the IAA production capability of the microbes was evaluated by supplementing the LB-broth with 100 or 200 mg L^-1 of CP in presence of 100 µg mL^-1 tryptophan.

Phosphate solubilization

The ability of the bacteria to solubilize phosphate was determined by plating the bacteria on Pikovskaya agar medium as per the method described previously.¹⁵15 Chakraborty U, Chakraborty BN, Basnet M, Chakraborty AP. Evaluation of Ochrobactrum anthropi TRS-2 and its talc based formulation for enhancement of growth of tea plants and management of brown root rot disease. J Appl Microbiol. 2009;107:625-634. The presence of a clear zone around bacterial colonies following one week of incubation at 35 °C indicated phosphate solubilization. Phosphate solubilization was analyzed by computing the Solubilization Index (SI) which is the ratio of total diameter (colony + halo) to colony diameter. The effect of CP on the phosphate solubilization ability of the bacteria was determined by supplementing Pikovskaya agar plates with 100 and 200 mg L^-1 chlorpyrifos.

Ammonia production

McCartney bottles containing 10 mL peptone water were inoculated with bacterial strains in triplicate and incubated at 35 °C for 96 h. The NH₃ production was detected by observing the formation of yellow colour in the bottle upon addition of Nessler's reagent and intensity of the colour produced was noted.¹⁶16 Akbar S, Sultan S, Kertesz M. Determination of cypermethrin degradation potential of soil bacteria along with plant growth-promoting characteristics. Curr Microbiol. 2015;70:75-84. The effect of CP on ammonia production by bacterial strains under study was evaluated by the addition of 100-200 mg L^-1 CP to peptone water.

Biodegradation studies

Inoculum preparation

Seed culture for each isolate was grown in a nutrient broth containing 50 mg L^-1 CP. Following growth, the cultures were centrifuged at 4600 × g for 5 min, washed and then diluted with MilliQ H₂O. Colony forming units (cfu mL^-1) of these suspensions were determined by the dilution plate counting method. For pesticide biodegradation studies, a cell concentration corresponding to 1.6 × 10⁷ cfu mL^-1 was used so as to maintain uniformity in cell numbers.

Chlorpyrifos degradation in liquid medium

Erlenmeyer flasks (250 mL) containing mineral salt medium (100 mL) supplemented with 100 mg L^-1 of CP were inoculated with bacterial cell suspension in triplicates. The flasks were incubated at 30 °C with shaking at 150 rpm and an uninoculated flask was used as control. For growth study analysis an aliquot of 1 mL culture was withdrawn at regular intervals of 2 days each for 10 continuous days and growth was evaluated as OD₆₀₀. CP residue extraction and estimation by HPLC was done as described previously.¹⁴14 Akbar S, Sultan S, Kertesz M. Bacterial community analysis in chlorpyrifos enrichment cultures via DGGE and use of bacterial consortium for CP biodegradation. World J Microbiol Biotechnol. 2014;30:2755-2766.

Biodegradation of chlorpyrifos in soil

Analysis of CP degradation by selected strains isolated from soil was conducted in sterilized (S) and non-sterilized (nS) soil samples. The required soil samples (100 g) were spiked with chlorpyrifos to a final concentration of 200 mg kg^-1 by the addition of an acetone-based CP solution. The solution was initially added to a small portion (10 g) of soil, which, following the solvent evaporation was then mixed with the remaining soil quantity. The soil samples were inoculated and incubated at 30 °C. The test was performed in triplicate and uninoculated S and nS soils were used as controls. Sample removal, extraction and pesticide residue estimation were carried out as described earlier.¹⁴14 Akbar S, Sultan S, Kertesz M. Bacterial community analysis in chlorpyrifos enrichment cultures via DGGE and use of bacterial consortium for CP biodegradation. World J Microbiol Biotechnol. 2014;30:2755-2766.

Plant-microbe interaction and chlorpyrifos degradation

Pot experiments with Vigna unguiculata (L.) Walp. were conducted in order to examine the effects of bacterial inoculation on plant growth and pesticide degradation. Seeds of V. unguiculata were surface sterilized by treatment with 0.1% HgCl₂ solution for 5 min followed by washing with sterilized glass-distilled water. Soil samples (1.5 kg) were spiked with CP to a concentration of 200 mg kg^-1 using the same protocol as described above. Samples were then inoculated with microbial suspension to give final concentration of 1.6 × 10⁷ cells g^-1. The test was performed in triplicate and uninoculated spiked and non-spiked soil samples were used as control. Sterilized seeds of V. unguiculata were sown in the sample soils, and then the soil was moistened with water. Care was taken to ensure that the pots were kept at ambient light and temperature. The seed emergence process was observed daily and plants were allowed to grow for 6 weeks. The following parameters of plant growth were recorded: (a) percentage of germination, (b) shoot length (cm), (c) root length (cm), (d) leaf length (cm), (e) shoot fresh weight (g), (f) root fresh weight (g), (g) shoot dry weight (g), and (h) root dry weight (g).

Data analysis

The CP degradation rate constant (k) was determined using the kinetic model C_t = C₀ × e^-kt as described in a previous study.¹⁶16 Akbar S, Sultan S, Kertesz M. Determination of cypermethrin degradation potential of soil bacteria along with plant growth-promoting characteristics. Curr Microbiol. 2015;70:75-84. Statistical analysis was performed using the IBM SPSS 20 program. Significance (p < 0.05) of differences was analyzed by t-test or one-way ANOVA and assessed by post-hoc comparison of means using the Duncan's multiple range test.

Results

Isolation and characterization of chlorpyrifos degrading strains

From the enrichment culture, several promising morphologically different colonies were isolated and purified. Purified isolates were grown in a mineral salt medium supplemented with CP (100 mg L^-1). Estimation of CP degradation potential by HPLC demonstrated that the isolates were able to degrade 25-84.4% of supplemented CP within a time frame of 10 days. Maximum CP degradation potential was exhibited by isolates JCp4 and FCp1 that degraded 84.4% and 76.8% of the applied CP, respectively. Based on biochemical characterization and 16S rRNA gene analysis, these isolates were identified as Achromobacter sp. and Ochrobactrum sp. The 16S rDNA sequences of strains JCp4 and FCp1 exhibited closest (99%) homology with Achromobacter xylosoxidans (AB547225, FJ639331) and Ochrobactrum sp. (KF479631, KF843719), respectively.

Bacterial growth and biodegradation of CP in liquid medium

The bacterial strains were able to utilize CP as the sole source of C and exhibited effective growth up to a period 6 days of incubation without undergoing an initial lag phase. Increase in growth was very slow between 6th and 8th day, and thereafter the decline phase was initiated (Fig. 1). CP degradation by bacterial strains was exhibited as a decrease in CP concentration that was proportional to increase in bacterial growth and a time dependent loss of CP was observed in bacterial cultures (Fig. 1). A. xylosoxidans JCp4 degraded 84.4% of CP at the rate of 7.9 mg L^-1 d^-1 while Ochrobactrum sp. FCp1 degraded 76.8% of CP at the rate of 7.3 mg L^-1 d^-1. In the control flasks, CP degradation, as a byproduct of abiotic losses, was insignificant (6%) at the end of 10 days. HPLC analysis also revealed that A. xylosoxidans JCp4 and Ochrobactrum sp. FCp1 were able to mineralize CP completely such that there was only a transient accumulation of the CP metabolic product TCP (3,5,6-trichloro-2-pyridinol).

Fig. 1
Degradation of chlorpyrifos (•-•) during growth (▲-▲) of bacterial strains in mineral salt medium at concentration of 100 mg L^-1. Error bars represent SD, and values are means of three replicates.

Determination of auxiliary characteristics

The plant growth-promoting activities of bacterial strains, both in the absence as well as in the presence of CP, were determined (Table 1). The bacterial strains under study exhibited a substantial production of IAA following 24 h of incubation. A concentration dependent increase in production of IAA was observed: JCp4 and FCp1 produced 15.6 and 15.8 µg mL^-1 of IAA at 50 µg mL^-1, 18.8 and 19.3 µg mL^-1 at 100 µg mL^-1, and 23.3 and 25.0 µg mL^-1 of IAA at 150 µg mL^-1 of tryptophan, respectively. When the effect of presence or absence of CP on IAA production was compared, it was revealed that there was a reduction in IAA production by 2.65% (JCp4) and 4.3% (FCp1) when CP was present at a concentration of 100 mg L^-1. A further increase in CP concentration (200 mg L^-1) suppressed IAA production and resulted in a drop in quantity of IAA produced by 10.6% (JCp4) and 9.2% (FCp1) (Table 1). Both the strains also showed phosphate-solubilizing activity by producing a clear halo around their growth in both conditions. However, phosphate solubilization activity was reduced at higher concentration of CP. Furthermore, bacterial strains were also found positive for ammonia production in both situations (Table 1).

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Table 1
Plant growth promoting activities of cypermethrin degrading strains in presence and absence of chlorpyrifos.

Soil bioremediation

The ability of selected bacterial strains to degrade CP in soil was studied using sterilized (SS) as well as non-sterilized soil (nSS). The CP degradation dynamics revealed significant differences (p < 0.05) between different treatments (Fig. 2, Table 2). Moreover, CP degradation in soil suggested a time dependent disappearance that followed first order kinetics. In uninoculated sterilized soil, the decrease in CP concentration was insignificant and it was found that 80% of the applied CP persisted till the end of the incubation period. In non-sterilized soil data clearly showed that indigenous microbes possessed the potential to degrade CP in the amount applied in the experiment and utilized 42.2% of the initial CP amount by the end of the incubation time. However, the initial phase of CP depletion was followed by a lag period of 7 days during which only 3% of initial CP was degraded. Following this phase, CP disappearance was then observed to increase considerably with a rate constant of 0.0111 d^-1, average rate of 2.01 mg kg^-1 d^-1 and T _1/2 of 62.45 days. Bacterial strains exhibited higher CP degradation potential in non-sterilized soils as compared to sterilized soil. A. xylosoxidans JCp4 degraded 100% of the applied CP within a time frame of 42 days with average rate of 4.57 and 4.76 mg kg^-1 d^-1 and rate constant of 0.0517 and 0.069 d^-1 in sterile and non-sterile soils, respectively. Half-life (T_1/2) of CP degradation by JCp4 increased from 10.07 days in non-sterile soil to 12.93 days in sterile soil. Ochrobactrum sp. FCp1 utilized 93% of applied CP with a rate constant and average rate of 0.0477 d^-1 and 4.40 mg kg^-1 d^-1 in sterilized soil and T _1/2 of 14.5 days. In contrast, in non-sterilized soil 100% of initially applied CP was degraded by FCp1 with rate constant of 0.064 d^-1, average rate of 4.76 mg kg^-1 d^-1 and T _1/2 of 10.6 days (Fig. 2, Table 2).

Fig. 2
Degradation dynamics of chlorpyrifos in different soil treatments with initial CP concentration of 200 mg kg^-1 soil. Symbols: (♦) sterilized soil (SS) or SS inoculated with CP degrading strains, (•) non-sterilized soil (nSS) or nSS inoculated with CP degrading strains, and (▲) planted soil (PS) or PS inoculated with CP degrading strains. Values are the means of three replicates and error bars represent SD.

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Table 2
Kinetic studies of chlorpyrifos degradation in various microbiologically active soils. The initial chlorpyrifos concentration was 200 mg kg⁻¹ soil.

Growth experiment with V. unguiculata (L.) Walp

Influence of bacterial presence on plant growth and pesticide degradation was studied using plant growth experiments. CP addition to soil affected a reduction in certain plant parameters such as % germination (14.2%), shoot length (2 cm), shoot fresh weight (0.29 g), root fresh weight (0.05 g), shoot dry weight (0.2 g) and root dry weight (0.02 g). Plants grown in CP supplemented soils inoculated with CP-degrading bacterial strains exhibited significant enhancement in growth in terms of height and weight. An increase of 6.5 and 7.8 cm in shoot length and of 12.1 and 7.3 cm in root length was observed in case of JCp4 and FCp1, respectively. Leaf length was enhanced up to 2.1 cm. The increase in shoot weight increase was studied in terms of fresh and dry shoot weight; an increase of 1.6 and 1.17 g in shoot fresh weight and of 0.4 and 0.5 g in shoot dry weight was observed in plants inoculated with JCp4 and FCp1, respectively. Root weight was also enhanced significantly; JCp4 and FCp1 enhanced root fresh weight by 1.36 and 1.54 g and root dry weight by 0.15 and 0.16 g, respectively (Fig. 3, Table 3).

Fig. 3
Growth experiment with V. unguiculata in soil supplemented with CP (200 mg kg^-1). Control, without CP and bacterial inoculation; CP, no inoculum; CP + JCp4, inoculated with A. xylosoxidans JCp4 and CP + FCp1, inoculated with Ochrobactrum sp. FCp1.

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Table 3
Measurement of growth parameters of V. unguiculata in different microbiologically active soils supplemented with CP (200 mg kg⁻¹).

Within six weeks 48% of CP was degraded in un-inoculated soils at the rate of 2.27 mg kg^-1 d^-1 and rate constant of 0.0128 d^-1. The half-life of CP in un-inoculated planted soils was calculated to be 54.15 days. In inoculated soils 100% of applied CP was degraded within 35 d with average rate of 5.7 mg kg^-1 d^-1. A. xylosoxidans JCp4 degraded 93.3% CP in planted soil with rate constant of 0.088 d^-1 and T_1/2 was observed to be 7.86 days. Ochrobactrum sp. FCp1 utilized 89% CP within 28 days with rate constant of 0.079 d^-1 and T_1/2 of 8.77 days (Fig. 2, Table 2).

Discussion

Chlorpyrifos is a very popular pesticide that is used extensively for the purpose of pest control in vegetable and cotton fields. However, it is well known that CP is toxic for mammals and can lead to contamination of soil and water resources which makes its removal from the environment an extremely urgent issue. Bioremediation is a process that utilizes the degradation potential of microbes to provide a cost-effective and reliable approach for pesticide abatement. To this purpose, CP degrading bacterial strains were isolated from contaminated agricultural soil samples. Two promising CP-degrading isolates that were identified were A. xylosoxidans JCp4 and Ochrobactrum sp. FCp1 which were found to degrade 84.4% and 78.6% of CP (100 mg L^-1), respectively, within a time period of 10 days. In a few previously published reports, Achromobacter¹⁷17 Zhang R, Cui Z, Jiang J, He J, Gu X, Li S. Diversity of organophosphorus pesticide-degrading bacteria in a polluted soil and conservation of their organophosphorus hydrolase genes. Can J Microbiol. 2005;51:337-343. and Ochrobactrum¹⁸18 Wang B, Ma Y, Zhou W, et al. Biodegradation of synthetic pyrethroids by Ochrobactrum tritici strain pyd-1. World J Microbiol Biotechnol. 2011;27:2315-2324.^,¹⁹19 Zhai Y, Li K, Song J, Shi Y, Yan Y. Molecular cloning, purification and biochemical characterization of a novel pyrethroid-hydrolyzing carboxylesterase gene from Ochrobactrum anthropi YZ-1. J Hazard Mater. 2012;221-222:206-212. have been studied for their role in pesticide biodegradation but, to the best of our knowledge, this is the first study that aimed to analyze simultaneously CP degradation and plant growth promotion by these bacterial strains.

For analyzing CP degradation, an inoculum size of 1.6 × 10⁷ cfu g^-1 was used. Incidentally, it was noted that the inoculum density used was capable of removing CP proficiently without undergoing a lag phase. As reported in previous studies inoculum density is an essential factor influencing the efficient degradation of applied pesticides. In a previous report it was found that an inoculum density greater than 10⁶ cfu g^-1 was capable of degrading chlorpyrifos without lag phase.²⁰20 Singh BK, Walker A, Morgan JA, Wright DJ. Biodegradation of chlorpyrifos by Enterobacter strain B-14 and its use in bioremediation of contaminated soils. Appl Environ Microbiol. 2004;70:4855-4863. One possible explanation for requiring a high initial inoculum density for pesticide degradation could be that a higher number of bacteria are required to start and sustain fast degradation during incubation. Soil degradation studies revealed that the selected CP-degrading strains were capable of degrading CP both in liquid media as well as in soil. Previous studies on pesticide degradation have reported that microbes that are capable of degrading these compounds in culture media are also capable of degradation in soil.³3 Lu P, Li Q, Liu H, et al. Biodegradation of chlorpyrifos and 3,5,6-trichloro-2-pyridinol by Cupriavidus sp DT-1. Bioresour Technol. 2013;127:337-342.^,²¹21 Lakshmi CV, Kumar M, Khanna S. Biodegradation of chlorpyrifos in soil by enriched cultures. Curr Microbiol. 2009;58:35-38.^,²²22 Singh B, Walker A, Wright D. Bioremedial potential of fenamiphos and chlorpyrifos degrading isolates: influence of different environmental conditions. Soil Biol Biochem. 2006;38:2682-2693. The degradation kinetics were determined using first order rate equation C_t = C₀ × e^-kt because the pesticide disappearance was noted to be time-dependent. The rate constants for CP degradation by bacterial strains in soil ranged from 0.047 to 0.069 d^-1 with T_1/2 of 10-14.5 days. Similar first order rate equations have been used to study degradation kinetics of pesticides in soil in a few previously published reports.²³23 Chen S, Luo J, Hu M, Lai K, Geng P, Huang H. Enhancement of cypermethrin degradation by a coculture of Bacillus cereus ZH-3 and Streptomyces aureus HP-S-01. Bioresour Technol. 2012;110:97-104.^,²⁴24 Cycon M, Wojcik M, Piotrowska-Seget Z. Biodegradation of the organophosphorus insecticide diazinon by Serratia sp. and Pseudomonas sp. and their use in bioremediation of contaminated soil. Chemosphere. 2009;76:494-501. Comparable degradation kinetic values have been reported in earlier studies that analyzed degradation of CP. For example, Cycon et al. noted that Serratia marcescens was capable of degrading CP at rate constant ranging from 0.017 to 0.052 d^-1 with T _1/2 of 13.6-37 days in different types of soils.²⁵25 Cycon M, Zmijowska A, Wojcik M, Piotrowska-Seget Z. Biodegradation and bioremediation potential of diazinon-degrading Serratia marcescens to remove other organophosphorus pesticides from soils. J Environ Manage. 2013;117:7-16.

CP degradation was observed to be higher in uninoculated non-sterilized soils (42.2%) as compared to sterilized soils (17.2%). This finding demonstrates that CP degradation is mediated by soil microflora and that indigenous microbes are capable of degrading CP. In earlier studies, authors observed an 80% increase in diazinon degradation in non-sterilized soils as compared to sterilized soils.²⁴24 Cycon M, Wojcik M, Piotrowska-Seget Z. Biodegradation of the organophosphorus insecticide diazinon by Serratia sp. and Pseudomonas sp. and their use in bioremediation of contaminated soil. Chemosphere. 2009;76:494-501. Degradation of CP was high in inoculated non-sterile soils as compared to inoculated sterile soils indicating the bioremediation potential of CP degrading strains. An increase in CP-degradation was observed in non-sterile soils supplemented with CP-degrading strains A. xylosoxidans JCp4 (9.6%) and Ochrobactrum sp. FCp1 (7.75%). The observed enhancement in CP utilization can be attributed to the fact that inoculation of soil with degrading bacteria leads to an increase in its catabolic potential. Also, the ability of the indigenous microbes to utilize the applied pesticide compound most likely played a synergistic role in their biodegradation. Increased rate of depletion of pesticides in contaminated soils by augmentation of potential degrading strains has been observed in earlier studies. For instance, Burkholderia sp. FDS-1 enhanced the fenitrothion utilization rate when inoculated in FT contaminated soil containing native microflora.²⁶26 Hong Q, Zhang Z, Hong Y, Li S. A microcosm study on bioremediation of fenitrothion-contaminated soil using Burkholderia sp FDS-1. Int Biodeterior Biodegrad. 2007;59:55-61. In a similar vein, S. marcescens degraded deltamethrin more efficiently in non-sterile soils as compared to sterile soils.²⁷27 Cycoń M, Żmijowska A, Piotrowska-Seget Z. Enhancement of deltamethrin degradation by soil bioaugmentation with two different strains of Serratia marcescens. Int J Environ Sci Technol. 2013;11:1305-1316.

Determination of plant growth promoting characteristics revealed presence of substantial phosphate solubilization, IAA and ammonia production by CP degrading strains. Bacterial stains belonging to genera Achromobacter²⁸28 Jha P, Kumar A. Characterization of novel plant growth promoting endophytic bacterium Achromobacter xylosoxidans from wheat plant. Microb Ecol. 2009;58:179-188. and Ochrobactrum¹⁵15 Chakraborty U, Chakraborty BN, Basnet M, Chakraborty AP. Evaluation of Ochrobactrum anthropi TRS-2 and its talc based formulation for enhancement of growth of tea plants and management of brown root rot disease. J Appl Microbiol. 2009;107:625-634. have been isolated and studied for their plant growth promoting traits. Usually bacteria from plant rhizosphere and bulk agricultural soil possess plant growth promoting traits; some of these microbes also contain pesticide degrading capacities as a result of continuous exposure to these compounds. In earlier studies, diverse bacterial strains isolated from a soil enrichment culture responsible for thiamethoxam degradation were also found to possess IAA production and N₂-fixation abilities.¹³13 Zhou GC, Wang Y, Ma Y, et al. The metabolism of neonicotinoid insecticide thiamethoxam by soil enrichment cultures, and the bacterial diversity and plant growth-promoting properties of the cultured isolates. J Environ Sci Health B. 2014;49:381-390. Chlorpyrifos degrading Acinetobacter calcoaceticus also showed PGP traits.²⁹29 Zhao L, Wang F, Zhao J. Identification and functional characteristics of chlorpyrifos degrading and plant growth promoting bacterium Acinetobacter calcoaceticus. J Basic Microbiol. 2014;54:457-463. Significant decrease in PGP activities of CP-resistant bacteria was observed in presence of chlorpyrifos. CP has been previously reported to exert an inhibitory effect on soil microbial activities.²2 Fang H, Yu Y, Chu X, Wang X, Yang X, Yu J. Degradation of chlorpyrifos in laboratory soil and its impact on soil microbial functional diversity. J Environ Sci. 2009;21:380-386. Similarly, another study has also reported a decrease in plant-growth promoting traits of bacteria in presence of pesticides above the recommended dose.³⁰30 Madhaiyan M, Poonguzhali S, Hari K, Saravanan VS, Sa T. Influence of pesticides on the growth rate and plant-growth promoting traits of Gluconacetobacter diazotrophicus. Pest Biochem Physiol. 2006;84:143-154. Pesticides affect the soil microbiological activities by altering the population of cellulolytic and phosphate solubilizing microorganisms and thereby changing the nitrogen balance and ammonification of soil.³¹31 Ramani V. Effect of pesticides on phosphate solubilization by Bacillus sphaericus and Pseudomonas cepacia. Pest Biochem Physiol. 2011;99:232-236.

The growth of V. unguiculata was inhibited when soil was supplemented with 200 mg kg^-1 of CP. CP addition to soil also reduced certain plant parameters such as % germination (14.2%), shoot length (13.2%), shoot fresh weight (23.5%), root fresh weight (8.3%), shoot dry weight (40%) and root dry weight (20%). Bidlan et al. has reported that use of lindane at a concentration of 100 µg L^-1 inhibited the germination process in green gram and radish.³²32 Bidlan R, Afsar M, Manonmani HK. Bioremediation of HCH-contaminated soil: elimination of inhibitory effects of the insecticide on radish and green gram seed germination. Chemosphere. 2004;56:803-811. Different pesticides such as aldrin, carbofuran, fenamiphos and phorate have been found to have adverse effects on plant growth parameters such as plant height, weight and root nodulation.³³33 Tiyagi SA, Ajaz S, Azam MF. Effect of some pesticides on plant growth, root nodulation and chlorophyll content of chickpea. Arch Agron Soil Sci. 2004;50:529-533. The negative effect of pesticides on plant growth can be attributed to inhibition of electron flow in the photosynthetic chain. OPs and DDT have been found to affect photosynthesis by uncoupling the photosynthetic electron flow such that ATP synthesis is blocked.³⁴34 Mitra J, Raghu K. Pesticides-non target plants interactions: an overview. Arch Agron Soil Sci. 1998;43:445-500. Enhanced plant (V. unguiculata) growth was observed when soils were inoculated with CP bacterial strains. Following inoculation with A. xylosoxidans JCp4 and Ochrobactrum sp. FCp1, increase in plant growth was monitored by tracking parameters such as % germination (4.68%), plant height (59.6% and 48.6%), plant fresh weight (193.8% and 176.6%) and plant dry weight (137.5% and 165%). The enhanced rate of seed germination and plant growth can be attributed to IAA production, phosphate solubilization and decrease in toxicity of pesticides owing to its increased degradation.

Degradation of CP was also studied in planted soils inoculated with bacterial strains. In CP supplemented soils, A. xylosoxidans JCp4 and Ochrobactrum sp. FCp1 utilized 93.3% and 88.9% of applied CP in 28 days and were found to degrade CP completely after 35 days. The increase of CP degradation in planted soil could be attributed to the greater pesticide degrading activity of the inoculated microbes. Plant roots secrete exudates that can serve as a source of carbon for microbial growth which in turn degrades pesticide at an accelerated rate. In several studies, the plant seedlings have been shielded from the toxic effects of various pesticides by bio-augmenting the soil with pesticide degrading bacteria.³²32 Bidlan R, Afsar M, Manonmani HK. Bioremediation of HCH-contaminated soil: elimination of inhibitory effects of the insecticide on radish and green gram seed germination. Chemosphere. 2004;56:803-811.^,³⁵35 Gangadhara KP, Kunhi AAM. Protection of tomato seed germination from the inhibitory effect of 2,4,5-trichlorophenoxyacetic acid by inoculation of soil with Burkholderia cepacia AC1100. J Agric Food Chem. 2000;48:4314-4319.

In conclusion, the CP-degrading bacterial isolates obtained as a result of this study exhibited strong CP-degradation potential and were able to bioremediate soil with CP concentration as high as 200 mg kg^-1. These bacterial strains were found to possess not only pesticide degrading capacities that lower the toxic effects of these pesticides on plants but also various other traits that helped in plant growth promotion. These traits included production of phytohormones such as IAA that enhance cell growth, solubilization of phosphate for root uptake and N₂-fixation for plant uptake. Collating efficient biodegradation potential along with multiple biological properties, these isolates have the potential to develop into valuable candidates for development of bioremediation strategies.

Associate Editor: Fernando Dini Andreote

Acknowledgements

The financial support for the PhD work was provided by Higher Education Commission (HEC), Islamabad, Pakistan through Indigenous scholarship for work in Pakistan and International Research Support Initiative Program (IRSIP) funds to visit the Faculty of Agriculture and Environment, University of Sydney.

REFERENCES

¹
Briceño G, Fuentes MS, Palma G, Jorquera MA, Amoroso MJ, Dieza MC. Chlorpyrifos biodegradation and 3,5,6-trichloro-2-pyridinol production by actinobacteria isolated from soil. Int Biodeterior Biodegrad 2012;73:1-7.
²
Fang H, Yu Y, Chu X, Wang X, Yang X, Yu J. Degradation of chlorpyrifos in laboratory soil and its impact on soil microbial functional diversity. J Environ Sci 2009;21:380-386.
³
Lu P, Li Q, Liu H, et al. Biodegradation of chlorpyrifos and 3,5,6-trichloro-2-pyridinol by Cupriavidus sp DT-1. Bioresour Technol 2013;127:337-342.
⁴
Jabeen H, Iqbal S, Anwar S. Biodegradation of chlorpyrifos and 3,5,6-trichloro-2-pyridinol by a novel rhizobial strain Mesorhizobium sp HN3. Water Environ J 2015;29:151-160.
⁵
Saulsbury MD, Heyliger SO, Wang K, Round D. Characterization of chlorpyrifos-induced apoptosis in placental cells. Toxicology 2008;244:98-110.
⁶
Shan M, Fang H, Wang X, Feng B, Chu XQ, Yu YL. Effect of chlorpyrifos on soil microbial populations and enzyme activities. J Environ Sci 2006;18:4-5.
⁷
Menon P, Gopal M, Prasad R. Influence of two insecticides, chlorpyrifos and quinalphos, on arginine ammonification and mineralizable nitrogen in two tropical soil types. J Agric Food Chem 2004;:7370-7376.
⁸
Marino D, Ronco A. Cypermethrin and chlorpyrifos concentration levels in surface water bodies of the Pampa Ondulada, Argentina. Bull Environ Contam Toxicol 2005;75:820-826.
⁹
Weston DP, You J, Lydy MJ. Distribution and toxicity of sediment-associated pesticides in agriculture-dominated water bodies of California's Central Valley. Environ Sci Technol 2004;38:2752-2759.
¹⁰
Brajesh KS, Walker A. Microbial degradation of organophosphorus compounds. FEMS Microbiol Rev 2006;30:428-471.
¹¹
Anwar S, Liaquat F, Khan QM, Khalid ZM, Iqbal S. Biodegradation of chlorpyrifos and its hydrolysis product 3,5,6-trichloro-2-pyridinol by Bacillus pumilus strain C2A1. J Hazard Mater 2009;168:400-405.
¹²
Bano N, Musarrat J. Characterization of a novel carbofuran degrading Pseudomonas sp. with collateral biocontrol and plant growth promoting potential. FEMS Microbiol Lett 2004;231:13-17.
¹³
Zhou GC, Wang Y, Ma Y, et al. The metabolism of neonicotinoid insecticide thiamethoxam by soil enrichment cultures, and the bacterial diversity and plant growth-promoting properties of the cultured isolates. J Environ Sci Health B 2014;49:381-390.
¹⁴
Akbar S, Sultan S, Kertesz M. Bacterial community analysis in chlorpyrifos enrichment cultures via DGGE and use of bacterial consortium for CP biodegradation. World J Microbiol Biotechnol 2014;30:2755-2766.
¹⁵
Chakraborty U, Chakraborty BN, Basnet M, Chakraborty AP. Evaluation of Ochrobactrum anthropi TRS-2 and its talc based formulation for enhancement of growth of tea plants and management of brown root rot disease. J Appl Microbiol 2009;107:625-634.
¹⁶
Akbar S, Sultan S, Kertesz M. Determination of cypermethrin degradation potential of soil bacteria along with plant growth-promoting characteristics. Curr Microbiol 2015;70:75-84.
¹⁷
Zhang R, Cui Z, Jiang J, He J, Gu X, Li S. Diversity of organophosphorus pesticide-degrading bacteria in a polluted soil and conservation of their organophosphorus hydrolase genes. Can J Microbiol 2005;51:337-343.
¹⁸
Wang B, Ma Y, Zhou W, et al. Biodegradation of synthetic pyrethroids by Ochrobactrum tritici strain pyd-1. World J Microbiol Biotechnol 2011;27:2315-2324.
¹⁹
Zhai Y, Li K, Song J, Shi Y, Yan Y. Molecular cloning, purification and biochemical characterization of a novel pyrethroid-hydrolyzing carboxylesterase gene from Ochrobactrum anthropi YZ-1. J Hazard Mater 2012;221-222:206-212.
²⁰
Singh BK, Walker A, Morgan JA, Wright DJ. Biodegradation of chlorpyrifos by Enterobacter strain B-14 and its use in bioremediation of contaminated soils. Appl Environ Microbiol 2004;70:4855-4863.
²¹
Lakshmi CV, Kumar M, Khanna S. Biodegradation of chlorpyrifos in soil by enriched cultures. Curr Microbiol 2009;58:35-38.
²²
Singh B, Walker A, Wright D. Bioremedial potential of fenamiphos and chlorpyrifos degrading isolates: influence of different environmental conditions. Soil Biol Biochem 2006;38:2682-2693.
²³
Chen S, Luo J, Hu M, Lai K, Geng P, Huang H. Enhancement of cypermethrin degradation by a coculture of Bacillus cereus ZH-3 and Streptomyces aureus HP-S-01. Bioresour Technol 2012;110:97-104.
²⁴
Cycon M, Wojcik M, Piotrowska-Seget Z. Biodegradation of the organophosphorus insecticide diazinon by Serratia sp. and Pseudomonas sp. and their use in bioremediation of contaminated soil. Chemosphere 2009;76:494-501.
²⁵
Cycon M, Zmijowska A, Wojcik M, Piotrowska-Seget Z. Biodegradation and bioremediation potential of diazinon-degrading Serratia marcescens to remove other organophosphorus pesticides from soils. J Environ Manage 2013;117:7-16.
²⁶
Hong Q, Zhang Z, Hong Y, Li S. A microcosm study on bioremediation of fenitrothion-contaminated soil using Burkholderia sp FDS-1. Int Biodeterior Biodegrad 2007;59:55-61.
²⁷
Cycoń M, Żmijowska A, Piotrowska-Seget Z. Enhancement of deltamethrin degradation by soil bioaugmentation with two different strains of Serratia marcescens Int J Environ Sci Technol 2013;11:1305-1316.
²⁸
Jha P, Kumar A. Characterization of novel plant growth promoting endophytic bacterium Achromobacter xylosoxidans from wheat plant. Microb Ecol 2009;58:179-188.
²⁹
Zhao L, Wang F, Zhao J. Identification and functional characteristics of chlorpyrifos degrading and plant growth promoting bacterium Acinetobacter calcoaceticus J Basic Microbiol 2014;54:457-463.
³⁰
Madhaiyan M, Poonguzhali S, Hari K, Saravanan VS, Sa T. Influence of pesticides on the growth rate and plant-growth promoting traits of Gluconacetobacter diazotrophicus Pest Biochem Physiol 2006;84:143-154.
³¹
Ramani V. Effect of pesticides on phosphate solubilization by Bacillus sphaericus and Pseudomonas cepacia Pest Biochem Physiol 2011;99:232-236.
³²
Bidlan R, Afsar M, Manonmani HK. Bioremediation of HCH-contaminated soil: elimination of inhibitory effects of the insecticide on radish and green gram seed germination. Chemosphere 2004;56:803-811.
³³
Tiyagi SA, Ajaz S, Azam MF. Effect of some pesticides on plant growth, root nodulation and chlorophyll content of chickpea. Arch Agron Soil Sci. 2004;50:529-533.
³⁴
Mitra J, Raghu K. Pesticides-non target plants interactions: an overview. Arch Agron Soil Sci 1998;43:445-500.
³⁵
Gangadhara KP, Kunhi AAM. Protection of tomato seed germination from the inhibitory effect of 2,4,5-trichlorophenoxyacetic acid by inoculation of soil with Burkholderia cepacia AC1100. J Agric Food Chem 2000;48:4314-4319.

Publication Dates

Publication in this collection
Jul-Sep 2016

History

Received
29 Apr 2015
Accepted
21 Sept 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] Associate Editor: Fernando Dini Andreote

Bacterial strains	Trp (µg mL⁻¹)	IAA (µg mL⁻¹)	CP conc. (mg L⁻¹)	IAA (µg mL⁻¹)	Phosphate solubilization		NH₃ production
					Zone size (mm)	SI
Achromobacter xylosoxidans JCp4	50	15.6 ± 0.4^a	Control	18.8 ± 0.04^e	17 ± 0.57^e	4.2^e	+++
	100	18.8 ± 0.26^c	100	18.3 ± 0.14^d	16 ± 0.5^d	4.0^d	+++
	150	23.3 ± 0.3^e	200	16.8 ± 0.24^b	11 ± 1.0^c	3.6^b	++

Ochrobactrum sp. FCp1	50	15.8 ± 0.34^b	Control	18.3 ± 0.015^d	11 ± 1.0^c	3.8^c	+++
	100	19.3 ± 0.41^d	100	17.5 ± 0.02^c	10.5 ± 0.5^b	3.6^b	+++
	150	25.0 ± 0.5^f	200	16.6 ± 0.014^a	10 ± 0.0^a	3.3^a	++

Soil treatment	Regression equation	Δk (d⁻¹)^A A Linear equation between ln(Ct/C 0) of chemical data and time yielded regression equation and regression coefficient (R 2).	ΔV (mg kg⁻¹ d⁻¹)^B B Degradation rate constant (k) calculated using Ct = C 0 × e−kt . Ct residual concentration of CP (mg kg−1).	T_1/2 (d)^D D Disappearance time calculated by T 1/2 = ln 2/k.	R ² ^C C Chlorpyrifos disappearance rate.
SS	ln(C _t /C ₀) = −0.004t − 0.015	0.0053^a	0.84^a	130.7^l	0.983
nSS	ln(C _t /C ₀) = −0.013t+ 0.025	0.0111^b	2.01^b	62.45^k	0.985
PS	ln(C _t /C ₀) = −0.016t+ 0.042	0.0128^a	2.27^a	54.15^d	0.982

SS + JCp4	ln(C _t /C ₀) = −0.063t+ 0.231	0.0517^e	4.57^h	12.93^e	0.941
nSS + JCp4	ln(C _t /C ₀) = −0.089t+ 0.257	0.0688ⁱ	4.76^j	10.07^a	0.922
PS + JCp4	ln(C _t /C ₀) = −0.092t+ 0.194	0.088^c	5.69^b	7.86^a	0.944

SS + FCp1	ln(C _t /C ₀) = −0.058t+ 0.159	0.0476^g	4.40^g	14.56^f	0.953
nSS + FCp1	ln(C _t /C ₀) = −0.078t+ 0.173	0.064^h	4.76^j	10.83^b	0.972
PS + FCp1	ln(C _t /C ₀) = −0.076t+ 0.141	0.079^b	5.69^b	8.77^c	0.962

Growth parameters	Control	CP + Cowpea	CP + Cowpea + JCp4	CP + Cowpea + FCp1
% germination	87.5 ± 0.0^ab	75 ± 0.0^a	91.6 ± 6.4^b	91.6 ± 7.2^b
Shoot length (cm)	15.1 ± 0.36^b	13.1 ± 0.3^a	21.6 ±0.35^c	22.9 ± 0.36^d
Root length (cm)	16.1 ± 0.36^a	16 ± 0.31^a	28.2 ± 0.78^c	23.4 ± 0.82^b
Leaf length (cm)	3.03 ± 0.15^a	3.07 ± 0.15^a	5.15 ± 0.13^b	5.20 ± 0.1^b
Shoot fresh weight (g)	1.23 ± 0.07^b	0.94 ± 0.11^a	2.83 ± 0.10^d	2.40 ± 0.09^c
Root fresh weight (g)	0.6 ± 0.03^a	0.55 ± 0.07^a	1.96 ± 0.10^b	2.14 ± 0.06^c
Shoot dry weight (g)	0.3 ± 0.035^b	0.18 ± 0.006^a	0.7 ± 0.03^c	0.8 ± 0.01^d
Root dry weight (g)	0.1 ± 0.008^a	0.08 ± 0.007^a	0.25 ± .013^b	0.26 ± .003^b

Brasil

Brasil

Soil bacteria showing a potential of chlorpyrifos degradation and plant growth enhancement

ABSTRACT

Background:

Results:

Conclusion

Introduction

Materials and methods

Chemicals and media

Enrichment, selection and identification of chlorpyrifos degrading strains

Determination of auxiliary characteristics

Indole acetic acid (IAA) production

Phosphate solubilization

Ammonia production

Biodegradation studies

Inoculum preparation

Chlorpyrifos degradation in liquid medium

Biodegradation of chlorpyrifos in soil

Plant-microbe interaction and chlorpyrifos degradation

Data analysis

Results

Isolation and characterization of chlorpyrifos degrading strains

Bacterial growth and biodegradation of CP in liquid medium

Determination of auxiliary characteristics

Soil bioremediation

Growth experiment with V. unguiculata (L.) Walp

Discussion

Acknowledgements

REFERENCES

Publication Dates

History